New research stitches together the best parts of several different bacteria to synthesize a new biofuel product that matches current engines better than previously produced biofuels.

“My lab is interested in developing microbial biosynthetic processes to make biofuels, chemicals, and materials with tailored structures and properties,” says Fuzhong Zhang, associate professor at the School of Engineering & Applied Science at Washington University in St. Louis. “Previously, we engineered E.coli to produce a precursor compound that leads to the production of advanced biofuels. In this work, we took the next step toward the actual manufacture.”

Zhang’s research focuses on engineering metabolic pathways that, when optimized, allow the bacteria to act as a biofuel generator. In its latest findings, recently published in Biotechnology for Biofuels, Zhang’s lab used the best bits of several other species—including a well-known pathogen—to enable E. coli to produce branched, long-chain fatty alcohol (BLFL), a substance that can be used as a freeze-resistant, liquid biofuel.

New research indicates that poplar trees could be an economically viable biofuel material.

In the quest to produce affordable biofuels, poplars are one of the Pacific Northwest’s best bets—the trees are abundant, fast-growing, adaptable to many terrains, and their wood can become substances used in biofuel and high-value chemicals that we rely on in our daily lives.

But even as researchers test poplars’ potential to morph into everything from ethanol to chemicals in cosmetics and detergents, a commercial-scale processing plant for poplars has yet to be achieved. This is mainly because production costs still are not competitive with the current price of oil.

Now, a team of researchers is trying to make poplar a viable competitor by testing the production of younger poplar trees that could be harvested more frequently—after only two or three years—instead of the usual 10- to 20-year cycle.

Airlines are under pressure to reduce their carbon emissions, and are highly vulnerable to global oil price fluctuations. These challenges have spurred strong interest in biomass-derived jet fuels. Bio-jet fuel can be produced from various plant materials, including oil crops, sugar crops, starchy plants and lignocellulosic biomass, through various chemical and biological routes. However, the technologies to convert oil to jet fuel are at a more advanced stage of development and yield higher energy efficiency than other sources.

We are engineering sugarcane, the most productive plant in the world, to produce oil that can be turned into bio-jet fuel. In a recent study, we found that use of this engineered sugarcane could yield more than 2,500 liters of bio-jet fuel per acre of land. In simple terms, this means that a Boeing 747 could fly for 10 hours on bio-jet fuel produced on just 54 acres of land. Compared to two competing plant sources, soybeans and jatropha, lipidcane would produce about 15 and 13 times as much jet fuel per unit of land, respectively.

Researchers have created a new method to more efficiently convert potato waste into ethanol. The findings may lead to reduced production costs for biofuel in the future and add extra value for chip makers.

Using potato mash made from the peelings and potato residuals from a Pennsylvania food-processing company, researchers triggered simultaneous saccharification—the process of breaking down the complex carbohydrate starch into simple sugars—and fermentation—the process in which sugars are converted to ethanol by yeasts or other microorganisms in bioreactors.

The simultaneous nature of the process was innovative, according to researcher Ali Demirci, professor of agricultural and biological engineering at Penn State. The addition to the bioreactor of mold and yeast—Aspergillus niger and Saccharomyces cerevisiae, respectively—catalyzed the conversion of potato waste to bioethanol.

The bioreactor had plastic composite supports to encourage and enhance biofilm formation and to increase the microbial population. Biofilms are a natural way of immobilizing microbial cells on a solid support material. In a biofilm environment, microbial cells are abundant and more resistant to environmental stress causing higher productivities.

Biofuels have become a promising potential alternative for traditional fossil fuels. However, producing biofules only make sense if the greenhouse gasses emitted are less than other means of producing energy.

According to new research, sugarcane and nepiegrass could be two of the most promising candidates for biofuel production due to their ability to isolate more carbon dioxide in the soil than is lost in the atmosphere.

Sugarcane and nepiegrass both have large carbon-storing root biomass that can offset the carbon dioxide emitted during cultivation. To test this, researchers observed these plants in Hawaii over a two year period, measuring both the above- and below-ground biomass and resulting greenhouse gas flux.

Renewable energy is on the rise, but how we store that energy is still up for debate.

“Renewable energy is growing, but it’s intermittent,” says Grigorii Soloveichik, program director at the United States Department of Energy’s Advanced Research Projects Agency. “That means we need to store that energy and we have two ways to do that: electricity or liquid fuels.”

According to Soloveichik, electricity and batteries are sufficient for short term energy storage, but new technologies such as liquid fuels derived from renewable energy must be considered for long term storage.

During the PRiME 2016 meeting in October, Soloveichik presented a talk titled, “Development of Transformational Technologies,” where he described the advantages that carbon neutral liquid fuels have over other convention means – such as batteries – for efficient, affordable, long term storage for renewable energy sources.

Rise of renewables

In the United States, 16.9 percent of electricity generation comes from renewables – a 9.3 percent increase since 2015. Globally, climate talks such as the Paris Agreement help bolster the rise of renewable energy around the world. Soloveichik expects that growth to continue in light of the affordability of clean energy technologies and government mandates that aim at environmental protection and a reduction of the carbon footprint. However, the continued rise in renewable dependence will impact the current grid infrastructure.

“More renewables will result in more stress on the grid,” Soloveichik says. “All of these new sources are intermittent, so we need to be able to store huge amounts of energy.”

Cyanobacteria has been recognized by researchers as a promising platform for biofuel production since 2013. The bacteria—more commonly referred to as blue-green algae—has the ability to grow fast and fix carbon dioxide gas. Unlike many other forms of bacteria, they do not require fermentable sugars or arable land to grow.

While that all spells out promising potential for the transformation into biofuel, the productions methods have not been adequate to take this development to commercialization.

A ‘Green’ Revolution

Now, researchers from Michigan State University have found a way to streamline the molecular machinery that transforms cyanobacteria into biofuels. To do this, researchers fabricated a synthetic protein that can improve the bacteria’s ability to fix carbon dioxide gas as well as potentially improve plant photosynthesis.

“The multifunctional protein we’ve built can be compared to a Swiss Army knife,” says Raul Gonzalez-Esquer, a doctoral researcher at Michigan State University and one of the authors of the study. “From known, existing parts, we’ve built a new protein that does several essential functions.”

But extra garbage and financial strain are not the only things food waste produces, it also generates a huge amount of greenhouse gas during decomposition. More specifically, global food waste creates 3.3 billion tons of greenhouse gas annually.

The research gives scientists clues about the genes that control plant structures and how we can manipulate them to our advantage.Source: Paul Efland/UGA

Researchers at the University of Georgia (UGA) are looking to accelerate the biofuel industry with this new development in plant gene structure.

The UGA scientists have discovered that manipulating a certain gene in a hardwood tree makes easier the process of breaking wood into fuel, and simultaneously increases the pace of tree growth.

This from UGA:

In a paper published recently in Biotechnology for Biofuels, the researchers describe how decreasing the expression of a gene called GAUT12.1 leads to a reduction in xylan and pectin, two major components of plant cell walls that make them resistant to the enzymes and chemicals used to extract the fermentable sugars used to create biofuels.

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